Battery sub-packing unit and battery module including the same

ABSTRACT

A battery sub-packing unit includes a plurality of secondary battery cells, a cell support member including a seating portion for accommodating the plurality of secondary battery cells, and a venting inducing portion connecting the seating portion to an external area, and a case member provided to surround the secondary battery cell accommodated in the seating portion and to seal around the secondary battery cell.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application claims benefit of priority to Korean Patent ApplicationNo. 10-2020-0015130 filed on Feb. 7, 2020 and Korean Patent ApplicationNo. 10-2021-0011273 filed on Jan. 27, 2021 in the Korean IntellectualProperty Office, the disclosure of which is incorporated herein byreference in its entirety.

BACKGROUND 1. Field

Example embodiments of the present disclosure relate to a batterysub-packing unit and a battery module including the same.

2. Description of Related Art

As technological development and demand for mobile devices, electricvehicles, energy storage systems (ESS), and the like, have increased,the demand for a secondary battery cell as an energy source has rapidlyincreased. A secondary battery cell may be charged and dischargedrepeatedly in that mutual conversion between chemical energy andelectrical energy is reversible.

Such a secondary battery cell may include an electrode assemblyincluding a positive electrode, a negative electrode, a separator, andan electrolyte, major components of a secondary battery, and a cell bodymember of a laminated film case protecting the electrode assembly.

Such an electrode assembly may generate heat while going throughcharging and discharging, and a temperature increase caused by the heatgeneration may degrade performance of the secondary battery cell.

Also, when the heat generation becomes severe, internal pressure of thesecondary battery cell may increase such that the secondary battery cellmay be ignited.

Further, when a plurality of secondary battery cells are mounted as inan energy storage system (ESS), a secondary battery cell may explodealong with the above-described ignition, and the flame may spread to theneighboring secondary battery cells.

To address the above-described issues, a research on a batterysub-packing unit and a battery module including the same has beennecessary.

SUMMARY

An example embodiment of the present disclosure is to provide a batterysub-packing unit and a battery module including the same, which mayprevent propagation of ignition of a secondary battery cell, or mayshield secondary battery cells to prevent heat generated by one of thesecondary battery cell from spreading to a neighboring secondary batterycell.

Another example embodiment of the present disclosure is to provide abattery sub-packing unit and a battery module including the same, whichmay induce a flame to one side or may smother and extinguish the flamewhen the secondary battery cell is ignited.

According to an example embodiment of the present disclosure, a batterysub-packing unit includes a plurality of secondary battery cells, a cellsupport member including a seating portion for accommodating theplurality of secondary battery cells, and a venting inducing portionconnecting the seating portion to an external area, and a case memberprovided to surround the secondary battery cell accommodated in theseating portion and to seal around the secondary battery cell.

The venting inducing portion may be formed at one end of the cellsupport member, and forms a cross-sectional area greater than 0.1% of anarea of the one end and smaller than 10% of the area of the one end.

The venting inducing portion may be formed at one end of the cellsupport member, and forms a cross-sectional area of 5 to 99 mm².

The venting inducing portion may be formed at one end of the cellsupport member, and forms a cross-sectional area of 25 to 75 mm².

The cell support member may include a blocking member attached to anexternal side of one end of the cell support member on which the ventinginducing portion is formed, shielding the venting inducing portion, andopening the venting inducing portion by being detached when pressure inthe seating portion increases by explosion of the secondary batterycell.

The cell support member may include a liquid guide tab provided on anexternal side of one end of the cell support member on which the ventinginducing portion is formed, disposed on a lower side of the ventinginducing portion, and including a rail groove for guiding leakage ofelectrolyte caused by explosion of the secondary battery cell.

The case member is formed of a single metal material or an alloymaterial maintaining a shape thereof up to at least 800° C.

The case member is formed of iron (Fe) in a thickness of 0.45 to 2 mm,or is formed of aluminum (Al) in a thickness of 0.8 to 3 mm.

The case member may have one end configured to be closed and the otherend configured to be open, such that the one end and the other end maybe inserted into and coupled to an upper portion and a lower portion ofthe cell support member in which the secondary battery cell isaccommodated, respectively.

A coupling end, the other end, of the case member may be bent to beinserted into a coupling groove formed in the cell support member andmay be bent multiple times to include a notch shape, such that the casemember may be in close contact with the cell support member.

According to another example embodiment of the present disclosure, abattery module includes a plurality of secondary battery cells, abattery sub-packing unit including a cell support member accommodatingthe plurality of secondary battery cells and a case member configured tosurround the secondary battery cells, and a body frame member in which aplurality of the battery sub-packing units are installed.

In the battery sub-packing unit, the accommodated secondary battery cellmay be a pouch-type secondary battery cell or a lithium ion secondarybattery cell.

The battery module may further include a barrier member disposed betweenthe plurality of battery sub-packing units adjacent to each other andpreventing flame or heat from spreading.

The barrier member may be disposed between the plurality of casemembers, adjacent to each other and disposed with a gap of at least 7 mmtherebetween.

The barrier member may include a shielding surface disposed between thecase members adjacent to each other and having external surfacesopposing each other, and a support protrusion provided on the shieldingsurface and protruding in a direction of an external surface of the casemember.

The support protrusion may be configured to protrude to the shieldingsurface in a hemispherical shape or a pyramidal shape in point-contactwith the external surface of the case member.

The support protrusion may be configured to protrude to the shieldingsurface in a semicircular columnar shape or an angular columnar shape inline-contact with the external surface of the case member.

At least a portion of the shielding surface may have a bellows shape.

The barrier member may be formed of a thermosetting polymer material, apolyphenylene sulfide material, or a material including gypsum,maintaining a shape thereof up to at least 800° C.

BRIEF DESCRIPTION OF DRAWINGS

The above and other aspects, features, and advantages of the presentdisclosure will be more clearly understood from the following detaileddescription, taken in conjunction with the accompanying drawings, inwhich:

FIG. 1 is a perspective diagram illustrating a battery sub-packing unitaccording to an example embodiment of the present disclosure;

FIG. 2 is a perspective diagram illustrating a cell support member of abattery sub-packing unit according to an example embodiment of thepresent disclosure;

FIG. 3 is a perspective diagram illustrating a liquid guide tab portionof a battery sub-packing unit according to an example embodiment of thepresent disclosure:

FIG. 4A and FIG. 4B are a diagram illustrating a state in which abattery sub-packing unit includes a blocking member and a state in whichthe blocking member is removed according to an example embodiment of thepresent disclosure:

FIG. 5 is a cross-sectional diagram illustrating a battery sub-packingunit according to an example embodiment of the present disclosure;

FIG. 6 is a perspective diagram illustrating a state in which a casemember is separated from a battery sub-packing unit according to anexample embodiment of the present disclosure:

FIG. 7 is a perspective diagram illustrating a battery sub-packing unitand a battery module including the battery sub-packing unit according toan example embodiment of the present disclosure;

FIG. 8 is an exploded perspective diagram illustrating a batterysub-packing unit and a battery module including the battery sub-packingunit according to an example embodiment of the present disclosure;

FIG. 9 is a plan diagram illustrating a barrier member portion in abattery module according to an example embodiment of the presentdisclosure:

FIG. 10A and FIG. 10B are a cross-sectional diagram illustrating anexample embodiment of a barrier member in a battery module according toan example embodiment of the present disclosure;

FIG. 11A and FIG. 11B are a plan diagram illustrating an exampleembodiment in which a barrier member is in point-contact in a batterymodule according to an example embodiment of the present disclosure;

FIG. 12A and FIG. 12B are a plan diagram illustrating an exampleembodiment in which a barrier member is in line-contact in a batterymodule according to an example embodiment of the present disclosure:

FIG. 13 is a perspective diagram illustrating a barrier member in abattery module according to an example embodiment of the presentdisclosure; and

FIG. 14 is a plan diagram illustrating an example embodiment in which ashielding surface of a barrier member has a bellows shape in a batterymodule according to an example embodiment of the present disclosure.

DETAILED DESCRIPTION

Hereinafter, embodiments of the present disclosure will be described asfollows with reference to the accompanying drawings. The presentdisclosure may, however, be exemplified in many different forms andshould not be construed as being limited to the specific embodiments setforth herein. Rather, these embodiments are provided so that thisdisclosure will be thorough and complete, and will fully convey thescope of the disclosure to those skilled in the art. Accordingly, shapesand sizes of elements in the drawings may be exaggerated for cleardescription, and elements indicated by the same reference numeral aresame elements in the drawings.

The terms used in the following description are provided to explain aspecific example embodiment and are not intended to be limiting. Asingular term includes a plural form unless otherwise indicated. Theterms, “include,” “comprise.” “is configured to,” etc. of thedescription are used to indicate the presence of features, numbers,steps, operations, elements, parts or combination thereof, and may notexclude the possibilities of combination or addition of one or morefeatures, numbers, steps, operations, elements, parts or combinationthereof.

An example embodiment relates to a battery sub-packing unit 100 and abattery module including the same, which may prevent propagation ofignition of the secondary battery cell C or may shield the secondarybattery cells C to prevent heat generated by one secondary battery cellC from spreading to a neighboring secondary battery cell C.

In another aspect, a battery sub-packing unit 100 and a battery moduleincluding the same may induce a flame to one side or may smother andextinguish the flame when the secondary battery cell is ignited.

The battery module in the example embodiment may, when a plurality ofsecondary battery cells C are mounted as in an energy storage system(ESS), address the issue in which one of the one secondary battery cellC explodes or generated heat spreads to the other secondary battery cellC. and the secondary battery cells C explode consecutively.

FIG. 1 is a perspective diagram illustrating a battery sub-packing unit100 according to an example embodiment. FIG. 2 is a perspective diagramillustrating a cell support member 110 of a battery sub-packing unit 100according to an example embodiment. Referring to FIGS. 1 and 2, thebattery sub-packing unit 100 in an example embodiment may include aplurality of secondary battery cells C, a cell support member 110including a seating portion 111 for accommodating the plurality ofsecondary battery cells C, and a venting inducing portion 112 connectingthe seating portion III to an external area, and a case member 120provided to surround the secondary battery cell C accommodated in theseating portion 111 and to seal around the secondary battery cell C.

The battery sub-packing unit 100 in the example embodiment may induce aflame or a gas to the venting inducing portion 112 when the secondarybattery cell C explodes and a flame or a gas is generated. In otherwords, since the case member 120 is configured to surround the seatingportion 111 in which the secondary battery cell C is disposed, and theventing inducing portion 112 is formed in the cell support member 110,the flame or the gas caused by the explosion of the secondary batterycell C may be induced to the venting inducing portion 112 connected toan external area in which a pressure is lower than that of an internalarea of the seating portion 111.

Thus, since the cell support member 110 includes the seating portion 111on which the secondary battery cell C is seated, and includes theventing inducing portion 112, when the pressure in the seating portion111 is higher than that of the external area, the frame generated whilehigh-pressure gas is ejected to the venting inducing portion 112 mayalso be induced to the venting inducing portion 112.

The seating portion 111 may be configured such that a single secondarybattery cell C is seated or a plurality of secondary battery cells C areseated.

As an example, as illustrated in FIG. 2, the seating portion 111 may beformed above and below the cell support member 110, and a pair ofsecondary battery cells C may be provided to be in contact with each ofthe seating portions 111. The seating portion 111 may be configured tohave a hole shape, and the secondary battery cells C are in closecontact with each other when the plurality of secondary battery cells Care seated, such that an accommodation space of the secondary batterycell C may be reduced.

The venting inducing portion 112 may have a hole shape. However, anexample embodiment thereof is not limited thereto, and the ventinginducing portion 112 may be implemented by any element able to inducethe flame or the gas.

Also, by limiting the size of the venting inducing portion 112, thegenerated flame may be induced to an external area and may be smotherand extinguished.

The venting inducing portion 112 of the battery sub-packing unit 100 inan example embodiment may be formed on one end 110 a of the cell supportmember 110, and may be formed to have a cross-sectional area A2 smallerthan at least 10% of an area A1 of the one end 110 a. As an example, theventing inducing portion may form a cross-sectional area A2 larger than0.1% of the area A1 of the one end 110 a and smaller than 10% of thearea A1.

The ratio of the size of the cross-sectional area A2 of the ventinginducing portion 112 to the size of the area A1 of one end 110 a of thecell support member 110 in which the venting inducing portion 112 isformed may be limited.

Also, the size of the cross-sectional area A2 of the venting inducingportion 112 may be limited to an absolute area value. That is, theventing inducing portion 112 of the battery sub-packing unit 100 in theexample embodiment may be formed on the one end 110 a of the cellsupport member 110, and may have the cross-sectional area A2 of 5 to 99mm.

More preferably, the venting inducing portion 112 of the batterysub-packing unit 100 in the example embodiment may be formed on the oneend portion 110 a of the cell support member 110, and may have thecross-sectional area A2 of 25 to 75 mm².

By limiting the size of the cross-sectional area A2 of the ventinginducing portion 112, a flame may be induced to the venting inducingportion 112, and inflow of air to the venting inducing portion 112 fromthe external area may be blocked.

Since the pressure of the seating portion 111 is higher than that of theexternal area, the gas in the seating portion 111 may be ejected to theexternal area, and when the venting inducing portion 112 has anexcessively large size, external air may be partially induced to theseating portion 111. The venting inducing portion 112 may address theabove-described issue by limiting the sizes of the venting inducingportion 112.

Accordingly, as oxygen in the seating portion 111 is depleted, the flamein the seating portion 111 may be extinguished.

For example, when the cross-sectional area A2 of the venting inducingportion 112 is less than 10% of the area A1 of the one end 110 a of thecell support member 110 or less than 99 mm², the flame may be smotheredand extinguished.

More preferably, when the cross-sectional area A2 of the ventinginducing portion 112 is less than 75 mm², the effect of extinguishingflame may be increased.

Also, the venting inducing portion 112 may need to have a size in whichthe flame or gas generated by the seating portion 111 may be dischargedexternally.

For example, when the cross-sectional area A2 of the venting inducingportion 112 is greater than 0.1% of the area A1 of the one end 110 a ofthe cell support member 110 or greater than 5 mm², the venting inducingportion 112 may emit the flame or gas.

More preferably, when the cross-sectional area A2 of the ventinginducing portion 112 is greater than 25 mm², the effect of dischargingthe flame or gas externally may improve.

The limitation of the cross-sectional area A2 of the venting inducingportion 112 may be confirmed through the experimental results in Table 1below.

TABLE 1 Cross-sectional area of Whether venting inducing smotheringportion extinguishment (mm²) induced Comparative example 1 4 X Inventiveexample 1 25 O Inventive example 2 50 O Inventive example 3 75 OComparative example 2 100 X

In comparative example 1, as the cross-sectional area A2 of the ventinginducing portion 112 was too small, the flame or gas was not dischargedfrom the seating portion 111, such that pressure in the seating portion111 increased, and the portion other than the venting inducing portion112 exploded, and accordingly, the smothering extinguishment was notinduced.

In comparative example 2, as the cross-sectional area A2 of the ventinginducing portion 112 was too large, external oxygen flowed into theseating portion 111 such that the smothering extinguishment was notinduced.

Also, the venting inducing portion 112 may be configured to have anelongated slot hole to discharge the flame in the seating portion 111and to block the inflow of external air.

Also, the cell support member 110 may induce the flame to the externalarea while ejecting the gas in the seating portion 111 to the externalarea through the venting inducing portion 112, and electrolyte leakedfrom the secondary battery cell C may be discharged. In the exampleembodiment, a liquid guide tab 114 for guiding the leaking electrolytemay be formed, which will be described later with reference to FIG. 3.

Also, the cell support member 110 may include a blocking member 113 tomaintain the venting inducing portion 112 to be in a closed state in anormal state. The detailed description thereof will be described laterwith reference to FIG. 4A and FIG. 4B.

The case member 120 may be configured to surround the seating portion111 in which the secondary battery cell C is disposed. Accordingly, whena flame is generated by explosion of the secondary battery cell C, theflame may be guided to the venting inducing portion 112.

Also, a thickness and a material of the case member 120 may be limitedsuch that fire resistance against a flame may be secured when a flame isgenerated in the seating portion 111. The detailed description thereofwill be described later with reference to FIGS. 5 and 6.

Also, the case member 120 may be disposed to be inserted to upper andlower portions of the cell support member 110, and the shape of the endsthereof may be limited such that the case member 120 may be in closecontact with the cell support member 110. The detailed descriptionthereof will be described later with reference to FIGS. 5 and 6.

FIG. 3 is a perspective diagram illustrating a liquid guide tab 114portion of a battery sub-packing unit 100 according to an exampleembodiment. Referring to FIG. 3, the cell support member 110 of thebattery sub-packing unit 100 in an example embodiment may include aliquid guide tab 114 disposed on an external side of the one end 110 aof the cell support member 110 on which the venting inducing portion 112is formed, disposed on a lower side of the venting inducing portion 112,and including a rail groove 114 a for guiding leakage of the electrolytecaused by explosion of the secondary battery cell C.

The liquid guide tab 114 may be configured to guide the discharge of theelectrolyte leaked from the secondary battery cell C when the secondarybattery cell C explodes.

To this end, the liquid guide tab 114 may be disposed on a lower side ofthe venting inducing portion 112 to guide the discharged electrolytewhile ejecting the gas in the seating portion 111 to an external areathrough the venting inducing portion 112.

The liquid guide tab 114 may include a rail groove 114 a for guiding theelectrolyte. The rail groove 114 a may be formed in a length directionof the liquid guide tab 114 configured to extend from the ventinginducing portion 112 to an external side.

FIG. 4A and FIG. 4B are a diagram illustrating a state in which abattery sub-packing unit 100 includes a blocking member 113 and a statein which the blocking member 113 is removed according to an exampleembodiment. Referring to FIG. 4, the cell support member 110 of thebattery sub-packing unit 100 in an example embodiment may include ablocking member 113 attached to an external side of the one end 110 a ofthe cell support member 110, blocking the venting inducing portion 112,and opening the venting inducing portion 112 by being detached when thepressure in seating portion 111 increases due to the explosion of thesecondary battery cell C.

The cell support member 110 may include the blocking member 113 suchthat the venting inducing portion 112 may be maintained to be in aclosed state in a normal state.

By sealing the venting inducing portion 112 by the blocking member 113,natural extinguishing may be induced by exhaustion of oxygen at aninitial stage of flame generation in the seating portion 111.

The blocking member 113 may be detached to open the venting inducingportion 112 to eliminate the high-pressure environment in the seatingportion 111. Accordingly, when the plurality of secondary battery cellsC are provided in the seating portion 111, the issue in which thepressure increases by the explosion of one of the secondary batterycells C such that another secondary battery cell C explodes due to theincreased pressure may be prevented.

FIG. 5 is a cross-sectional diagram illustrating a battery sub-packingunit 100 according to an example embodiment. FIG. 6 is a perspectivediagram illustrating a state in which a case member 120 is separatedfrom a battery sub-packing unit 100 according to an example embodiment.Referring to FIGS. 5 and 6, the case member 120 of the batterysub-packing unit 100 in an example embodiment may be formed of a singlemetal material or an alloy material maintaining a shape thereof up to atleast 800° C.

The material of the case member 120 is not limited to iron or aluminum,and a metal material, or an alloy material, a mixture of a plurality ofmetals, which maintains a shape thereof at 800° C., may be used as thematerial of the case member 120 in the example embodiment.

As an example, the case member 120 of the battery sub-packing unit 100in the example embodiment may be formed of iron (Fe) in a thickness of0.45 mm to 2 mm or aluminum (Al) in a thickness of 0.8 mm to 3 mm.

The case member 120 may be formed of a metal material such that the casemember 120 may prevent the flame of the secondary battery cell C fromspreading.

Specifically, the material and thickness of the case member 120 may belimited because, by configuring the material and thickness as above,resistance against the generation of flame of the secondary battery cellC may be implemented and the amount of the material to be used may bereduced.

TABLE 2 Material Aluminum Iron Thickness (mm) 0.5 1.0 0.65 1.0 Whethercase member broken O X X X Maximum temperature of ignited 1360 760 13601360 secondary batters, cell (° C.) Maximum temperature of 790 120 160160 surrounding secondary battery cell (° C.) Whether flame spread O X XX

As indicated in Table 1 above, even when the case member 120 was formedof iron in a thickness of 0.65 mm, the case member 120 was not broken.Accordingly, the possibility of breakage of the case member 120 formedof iron in a thickness of 0.45 mm was low.

Even when the case member 120 is formed of aluminum in a thickness of atleast 1.0 mm, the case member 120 was not broken. Accordingly, thepossibility of breakage of the case member 120 formed of aluminum in athickness of 0.8 mm was low.

Thus, it has been indicated that, by limiting the material and thicknessrange of the case member 120 as above, breakage of the case member 120may be prevented such that no flame may spread.

As the case member 120 is formed of a metal material such as iron oraluminum, the case member 120 may also perform a cooling function ofdischarging heat generated by the secondary battery cell C to theexternal area.

The material and the thickness of the case member 120 may be limited toreduce the amount of the material to be used.

In other words, the case member 120 may be formed of iron in a thicknessof 2 mm, or may be formed of aluminum in a thickness of 3 mm to reducethe material.

The case member 120 of the battery sub-packing unit 100 in an exampleembodiment has one end configured to be closed and the other endconfigured to be open, such that that the one end and the other end maybe inserted into upper and lower portions of the cell support member 110in which the secondary battery cell C is accommodated, respectively.

To this end, as an example shape of the of the case member 120 in whichthe one end is closed and the other end is open, the case member 120 mayhave a “⊏” shape.

Accordingly, the secondary battery cell C may be accommodated in theupper end and the lower end of the cell support member 110, and the casemember 120 having a “⊏” shape may be coupled to the upper end and thelower end of the cell support member 110 and may surround the cellsupport member 110.

Accordingly, the case member 120 may surround the secondary battery cellC seated on the cell support member 110, and may thus induce the flamegenerated in the secondary battery cell C to the venting inducingportion 112.

In the case member 120 of the battery sub-packing unit 100 in an exampleembodiment, the a coupling end 120 a, the other end, may be bent to beinserted into a coupling groove 115 formed in the cell support member110 and may be bent multiple times, such that the case member 120 mayhave a notch shape to be in close contact with the cell support member110.

The case member 120 may be configured as above to be in close contactwith the support member 110. The shape of the coupling end 120 a of thecase member 120 may be limited because, by configuring the internal areaof the seating portion 111, other than the venting inducing portion 112,to be a sealed area, the flame generated in the seating portion 111 maybe induced to the flame inducing part 112.

The one end of the case member 120 may be configured to be closed, andthe coupling end 120 a, the other end, may be configured to be open tobe inserted into the cell support member 110. In this case, by limitingthe shape of the coupling end 120 a, the internal area of the seatingportion 111 other than the venting inducing portion 112 may be sealed.

The coupling end 120 a may be primarily bent in a direction of thecoupling groove 115, formed on the cell support member 110 in thethickness direction of the cell support member 110, and may besecondarily bent to have the notch shape to be in close contact with thecoupling groove 115.

FIG. 7 is a perspective diagram illustrating a battery sub-packing unit100 and a battery module including the battery sub-packing unitaccording to an example embodiment. FIG. 8 is an exploded perspectivediagram illustrating a battery sub-packing unit 100 and a battery moduleincluding the battery sub-packing unit according to an exampleembodiment.

Referring to FIGS. 7 and 8, a plurality of secondary battery cells C, abattery sub-packing unit 100 including a cell support member 110 foraccommodating the plurality of secondary battery cells C, and a casemember provided to surround the secondary battery cell C. and a bodyframe member 200 in which the plurality of battery sub-packing units 100are installed may be included.

The cell support member 110 of the battery module in the exampleembodiment may include a seating portion 111 for accommodating theplurality of the secondary battery cells C, and a venting inducingportion 112 connecting the seating portion 111 to an external area.

As the battery module in the example embodiment includes the batterysub-packing unit 100, a flame caused by the explosion of one of thesecondary battery cells C may be induced to the flame induction unit 112and additional explosion may be prevented.

The battery module in the example embodiment may further include abarrier member 300 to prevent propagation of flame between the batterysub-packing units 100, and a detailed description thereof will beprovided with reference to FIGS. 9 to 14.

The body frame member 200 may be configured to have a box form in whicha plurality of the battery sub-packing units 100 are accommodated, ormay be configured to include a connection member 210 having a bar shapein which the plurality of battery sub-packing units 100 are tied andconnected to each other.

When the battery sub-packing unit 100 is configured to be connected tothe connection member 210, a side wall cover member 220 for enclosing aside portion of the plurality of battery sub-packing units 100 connectedto each other by the connection member 210 may be included.

The secondary battery cell C may include an electrode assembly and acell body member surrounding the electrode assembly.

The electrode assembly may substantially include an electrolyte and maybe accommodated in the cell body member. The electrolyte may include alithium salt such as LiPF₆ or LiBF₄ in an organic solvent such asethylene carbonate (EC), propylene carbonate (PC), diethyl carbonate(DEC), ethyl methyl carbonate (EMC), dimethyl carbonate (DMC), or thelike. Furthermore, the electrolyte may be liquid, solid or gel-type.

The cell body member may be configured to protect the electrode assemblyand to accommodate the electrolyte. For example, the cell body membermay be configured as as a pouch-shaped member or a can-shaped member.The pouch-shaped member may accommodate the electrode assembly bysealing the electrode assembly on three surfaces. The electrode assemblymay be accommodated in the pouch-shaped member by three surfaces, anupper surface and both side surfaces other than a lower surface and onesurface, and the pouch-shaped member may be folded to seal the electrodeassembly. The can-shaped member may be configured to accommodate theelectrode assembly by sealing the electrode assembly on a singlesurface. The electrode assembly may be accommodated in the can-shapedmember by a single surface, an upper surface other than a lower surfaceand both side surfaces, and the can-shaped member may be folded to sealthe electrode assembly.

In the battery sub-packing unit 10) of the battery module in the exampleembodiment, the secondary battery cell C to be accommodated may beconfigured as a pouch-type secondary battery cell C or a lithium ionsecondary battery cell.

FIG. 9 is a plan diagram illustrating a barrier member 300 portion in abattery module according to an example embodiment. Referring to FIG. 9,a battery module in the example embodiment may include a barrier member300 disposed between the plurality of battery sub-packing units 100adjacent to each other and preventing flame or heat from spreading.

The barrier member 300 may be disposed between the battery sub-packingunits 100 adjacent to each other to prevent flame or heat from spreadingbetween the secondary battery cells C provided in each different batterysub-packing unit 100.

The barrier member 300 of the battery module in the example embodimentmay be disposed between the plurality of case members 120 adjacent toeach other with a spaced gap G of at least 7 mm therebetween.

The barrier member 300 may be configured as above because, when thethickness is 7 mm or greater, and a flame is generated by the secondarybattery cell C in the battery sub-packing unit 100 on one side, thespreading of fire to a neighboring secondary battery cell C may beprevented, and transfer of heat generated by the secondary battery cellC in the battery sub-packing unit 100 on one side to a neighboringbattery sub-packing unit 100 by radiation or conduction may be reduced.This configuration is indicated in Table 3 below.

TABLE 3 Temperature Temperature of of ignited neighboring secondarysecondary Whether Thickness battery cell battery cell flame Material(mm) Form (° C.) (° C.) spread Comparative PPS 6 Three 2 mm plates 10048.8 O example 3 Comparative PPS 6 Three 2 mm plates 130 59.4 O example4 Comparative PPS 6 Three 2 trim plates 160 77.7 O example 5 ComparativeBMC 5 One 5 mm plate 100 48.8 O example 6 Comparative BMC 5 One 5 mmplate 130 66.5 O example 7 Comparative BMC 5 One 5 mm plate 160 80.9 Oexample 8 Inventive PPS 12 Four 3 mm plates 100 27.4 X example 4Inventive PPS 12 Four 3 mm plates 130 40.4 X example 5 Inventive PPS 12Four 3 mm plates 160 50.8 X example 6 Inventive BMC 7 One 4 mm plate,100 32.8 X example 7 support protrusion of 1.5 mm on one surface, andsupport protrusion of 4 mm on the other surface Inventive BMC 7 One 4 mmplate, 130 43.9 X example 8 support protrusion of 1.5 mm on one surface,and support protrusion of 4 mm on the other surface Inventive Gypsum 7One 7 mm plate 100 39.3 X example 9 Inventive Gypsum 7 One 7 mm plate130 55.5 X example 10

In Table 2, PPS is an abbreviation of a polyphenylene sulfide material,and BMC is an abbreviation of a bulk molding compound material. Also,BMC may be, for example, a material including a thermosetting polymerthat maintains a shape thereof up to at least 800° C.

As indicated in Table 3, when the barrier member 300 was a PPS material,and the thickness was 6 mm, the fire spread, but when the thickness was12 mm, the fire did not spread. Also, when the barrier member 300 was aBMC material, and the thickness was 5 mm, the fire spread, but when thethickness was 7 mm, the fire did not spread. When the barrier member 300was gypsum, and the thickness was 7 mm, the fire did not spread.

Thus, it has been indicated that, when the thickness of the barriermember 300 was at least 7 mm, the barrier member 300 may have an effectof preventing fire from spreading.

However, since the barrier member 300 is disposed in a space between thebattery sub-packing units 100 adjacent to each other, the thickness ofat least 7 mm of the barrier member 300 may correspond to the gap Gbetween the battery sub-packing units 100 adjacent to each other, inwhich the barrier member 300 is disposed.

Thus, when the barrier member 300 is disposed between the case members120 adjacent to each other with a spaced gap G of at least 7 mmtherebetween, an effect of preventing fire spread may be obtained.

Also, the barrier member 300 may be configured to occupy overall spacebetween the case members 120 adjacent to each other, but to reduce theconduction effect by being in contact with the case member 120, thebarrier member 300 may include a support protrusion 320. The barriermember 300 may further include a shielding surface 310 corresponding toopposing external surfaces of the case members 120 adjacent to eachother to reduce radiant heat transfer between the adjacent case members120.

Specifically, the barrier member 300 of the battery module in theexample embodiment may include the shielding surface 310 disposedbetween the case members 120 adjacent to each other and having externalsurfaces opposing each other, and the support protrusion 320 disposed onthe shielding surface 310 and configured to be protrude in a directionof the external surface of the case member 120.

The shielding surface 310 may be configured to have a shape extending toan area corresponding to the external surface of the case member 120 inorder to block the transfer of radiant heat generated by the case member120. However, an example embodiment thereof is not limited thereto, andthe shielding surface 310 may have a shape opposing a portion of theexternal surface of the case member 120.

The shielding surface 310 may have a bellows shape, such that theshielding surface 310 may elastically absorb high-pressure energy causedby the explosion in the battery sub-packing unit 100 on one side and mayreduce the influence on the neighboring battery sub-packing unit 100 onthe other side. The detailed description thereof will be described laterwith reference to FIG. 14.

The support protrusion 320 may be configured to prevent the issue inwhich the case member 120 is pressed and in contact with the shieldingsurface 310 as the secondary battery cell C disposed in the case member120 swells. In other words, when the secondary battery cell C swells,the case member 120 may be pushed in the direction of the shieldingsurface 310. In this case, by including the support protrusion 320, theissue in which the case member 120 is pressed and in contact with theshielding surface 310 may be prevented.

Accordingly, the issue of increased heat conduction caused by theincreased contact area between the case member 120 and the shieldingsurface 310 may be prevented.

Also, when the support protrusion 320 is disposed between the casemembers 120 adjacent to each other, the support protrusion 320 may bedisposed to be in contact with the case member 120 or may be spacedapart from the support protrusion 320.

When the support protrusion 320 is disposed to be in contact with thecase member 120, the support protrusion 320 may also press the casemember 120 in the direction of the cell support member 110. In otherwords, the support protrusion 320 may press the case member 120 to be inclose contact with the cell support member 110.

To this end, the support protrusion 320 may be configured to have ashape in which the support protrusion 320 is in point-contact with thecase member 120 or a shape in which the support protrusion 320 is inline-contact with the case member 120. The detailed description thereofwill be described later with reference to FIGS. 10 to 13.

Also, the barrier member 300 of the battery module in the exampleembodiment may be formed of a thermosetting polymer material, apolyphenylene sulfide material or a material including gypsum,maintaining a shape thereof up to at least 800° C.

The material of the barrier member 300 as described above may securefire resistance such that the issue in which the flame generated in thebattery sub-packing unit 100 on one side is in direct contact with thebattery sub-packing unit 100 on the other side may be prevented.

Also, the material of the barrier member 300 may prevent radiant heattransfer or conduction heat transfer, thereby reducing the rate oftransfer of heat generated by the battery sub-packing unit 100 on oneside to the battery sub-packing unit 100 on the other side.

FIG. 10A and FIG. 10B are a cross-sectional diagram illustrating anexample embodiment of a barrier member 300 in a battery module accordingto an example embodiment. FIG. 11A and FIG. 11B are a plan diagramillustrating an example embodiment in which a barrier member 300 is inpoint-contact in a battery module according to an example embodiment.FIG. 12A and FIG. 12B are a plan diagram illustrating an exampleembodiment in which a barrier member 300 is in line-contact in a batterymodule according to an example embodiment. FIG. 13 is a perspectivediagram illustrating a barrier member 300 in a battery module accordingto an example embodiment.

Referring to the diagram, a support protrusion 320 of the battery modulein the example embodiment may be configured to have a hemisphericalshape or a pyramidal shape configured to be in point-contact with anexternal surface of the case member 120 and may protrude to theshielding surface 310.

Also, the support protrusion 320 of the battery module in the exampleembodiment may be configured to have a semicircular columnar shape or anangular columnar shape configured to be in line-contact with an externalsurface of the case member 120 and may protrude to the shielding surface310.

Thus, the support protrusion 320 may have a shape in point-contact withthe case member 120 or a shape in line-contact with the case member 120.

The shape of the support protrusion 320 may be limited as describedabove to reduce a rate of heat conduction when the support protrusion320 is in contact with the case member 120.

In other words, the shape may be limited as above such that the supportprotrusion 320 may be configured to not be in surface-contact with thecase member 120, thereby reducing the contact area.

As an example, as illustrated in FIG. 11A, the support protrusion 320may have a hemispherical shape configured to be in point-contact, or mayhave a pyramid shape configured to be in point-contact as illustrated inFIG. 1I B.

Also, as illustrated in FIG. 12A, the support protrusion 320 may have asemi-circular columnar shape configured to be in line-contact, or mayhave an angular columnar shape configured to be in line-contact asillustrated in FIG. 12B.

FIG. 10A is a cross-sectional diagram illustrating a hemispherical shapein which the support protrusion 320 is in point-contact or asemicircular column shape in which the support protrusion 320 is inline-contact, and FIG. 10B is a cross-sectional diagram illustrating anangular pyramid shape in which the support protrusion 320 is inpoint-contact or an angular columnar shape in which the supportprotrusion 320 is in line-contact.

FIG. 14 is a plan diagram illustrating an example embodiment in which ashielding surface 310 of a barrier member 300 has a bellows shape in abattery module according to an example embodiment. Referring to FIG. 14,at least a portion of the shielding surface 310 of the battery module inthe example embodiment may have a bellows shape.

The shielding surface 310 may have a bellows shape, such that theshielding surface 310 may elastically absorb high-pressure energy causedby the explosion in the battery sub-packing unit 100 on one side, andmay reduce the influence on the battery sub-packing unit 10 on the otherside.

In other words, when the high-pressure gas pressurizes the shieldingsurface 310, the shape of the shielding surface 310 with a bellows shapemay be elastically changed into a flat shape and may absorb thehigh-pressure kinetic energy as deformation energy. Accordingly, theinfluence of the explosion energy generated by the battery sub-packingunit 100 on one side on the adjacent battery sub-packing unit 100 may bereduced.

According to the aforementioned example embodiment, the batterysub-packing unit and the battery module including the same may preventpropagation of ignition of a secondary battery cell or may shieldsecondary battery cells to prevent heat generated by one of thesecondary battery cell from spreading to another secondary battery cell.

Also, the battery sub-packing unit and the battery module including thesame may induce a flame to one side or may smother and extinguish theflame when the secondary battery cell is ignited.

While the example embodiments have been illustrated and described above,it will be apparent to those skilled in the art that modifications andvariations could be made without departing from the scope of the presentdisclosure as defined by the appended claims.

What is claimed is:
 1. A battery sub-packing unit, comprising: aplurality of secondary battery cells; a cell support member including aseating portion for accommodating the plurality of secondary batterycells, and a venting inducing portion connecting the seating portion toan external area; and a case member provided to surround the secondarybattery cell accommodated in the seating portion and to seal around thesecondary battery cell.
 2. The battery sub-packing unit of claim 1,wherein the venting inducing portion is formed at one end of the cellsupport member, and forms a cross-sectional area greater than 0.1% of anarea of the one end and smaller than 10% of the area of the one end. 3.The battery sub-packing unit of claim 1, wherein the venting inducingportion is formed at one end of the cell support member, and forms across-sectional area of 5 to 99 mm².
 4. The battery sub-packing unit ofclaim 1, wherein the venting inducing portion is formed at one end ofthe cell support member, and forms a cross-sectional area of 25 to 75mm².
 5. The battery sub-packing unit of claim 1, wherein the cellsupport member includes a blocking member attached to an external sideof one end of the cell support member on which the venting inducingportion is formed, shielding the venting inducing portion, and openingthe venting inducing portion by being detached when pressure in theseating portion increases by explosion of the secondary battery cell. 6.The battery sub-packing unit of claim 1, wherein the cell support memberincludes a liquid guide tab provided on an external side of one end ofthe cell support member on which the venting inducing portion is formed,disposed on a lower side of the venting inducing portion, and includinga rail groove for guiding leakage of electrolyte caused by explosion ofthe secondary battery cell.
 7. The battery sub-packing unit of claim 1,wherein the case member is formed of a single metal material or an alloymaterial maintaining a shape thereof up to at least 800° C.
 8. Thebattery sub-packing unit of claim 7, wherein the case member is formedof iron (Fe) in a thickness of 0.45 to 2 mm, or is formed of aluminum(Al) in a thickness of 0.8 to 3 mm.
 9. The battery sub-packing unit ofclaim 1, wherein the case member has one end configured to be closed andthe other end configured to be open, such that the one end and the otherend are inserted into and coupled to an upper portion and a lowerportion of the cell support member in which the secondary battery cellis accommodated, respectively.
 10. The battery sub-packing unit of claim1, wherein a coupling end, the other end, of the case member is bent tobe inserted into a coupling groove formed in the cell support member andis bent multiple times to include a notch shape, such that the casemember is in close contact with the cell support member.
 11. A batterymodule, comprising: a plurality of secondary battery cells; a batterysub-packing unit including a cell support member accommodating theplurality of secondary battery cells and a case member configured tosurround the secondary battery cells; and a body frame member in which aplurality of the battery sub-packing units are installed.
 12. Thebattery module of claim 11, wherein, in the battery sub-packing unit,the accommodated secondary battery cell is a pouch-type secondarybattery cell or a lithium ion secondary battery cell.
 13. The batterymodule of claim 11, further comprising: a barrier member disposedbetween the plurality of battery sub-packing units adjacent to eachother and preventing flame or heat from spreading.
 14. The batterymodule of claim 13, wherein the barrier member is disposed between theplurality of case members, adjacent to each other and disposed with agap of at least 7 mm therebetween.
 15. The battery module of claim 13,wherein the barrier member includes: a shielding surface disposedbetween the case members adjacent to each other and having externalsurfaces opposing each other; and a support protrusion provided on theshielding surface and protruding in a direction of an external surfaceof the case member.
 16. The battery module of claim 15, wherein thesupport protrusion is configured to protrude to the shielding surface ina hemispherical shape or a pyramidal shape in point-contact with theexternal surface of the case member.
 17. The battery module of claim 15,wherein the support protrusion is configured to protrude to theshielding surface in a semicircular columnar shape or an angularcolumnar shape in line-contact with the external surface of the casemember.
 18. The battery module of claim 15, wherein at least a portionof the shielding surface has a bellows shape.
 19. The battery module ofclaim 13, wherein the barrier member is formed of a thermosettingpolymer material, a polyphenylene sulfide material, or a materialincluding gypsum, maintaining a shape thereof up to at least 800° C.